Method for NMR spectroscopy

ABSTRACT

A method for performing magnetic resonance spectroscopy on solid samples containing nuclei of interest with spin quantum number I subjects the sample to a static magnetic field. The sample is spun at the magic angle and broad-band excitation of transverse magnetization of the nuclei of interest is effected by applying a first train of rotor-synchronized rf-pulses, having a carrier frequency, to the nuclei of interest with a pulse duration 0.1 μs&lt;τ p &lt;2 μs, the first train of rf-pulses comprising k·n pulses extending over k rotor periods τ rot  with n pulses per rotor period τ rot , wherein n is an integer n&gt;1. Uniform excitation of a great number of spinning sidebands or families of sidebands that arise from large first-order quadrupole or hyperfine interactions is enabled and signal intensity is thereby improved.

This application claims Paris Convention priority of EP 11 157 398.6 filed Mar. 9, 2011 the complete disclosure of which is hereby incorporated by reference.

BACKGROUND OF THE INVENTION

The invention concerns a method for performing magnetic resonance spectroscopy on solid sample containing nuclei of interest with spin quantum number I, comprising: subjecting the sample to a static magnetic field, spinning the sample at the magic angle and broad-band excitation of transverse magnetization of the nuclei of interest.

Related methods are known from [6].

Nitrogen plays structural and functional roles of fundamental importance in proteins and nucleic acids that are essential to many processes in living organisms. Nitrogen-14 is potentially an attractive spectroscopic probe because of its favorable isotopic abundance (99.6%) and reasonable gyromagnetic ratio (˜70% of ¹⁵N). However, ¹⁴N NMR is not yet a well-established spectroscopic technique. Unlike nuclei with spin S=½ such as ¹³C and ¹⁵N, ¹⁴N has a spin I=1 and a nuclear quadrupole moment Q. The interaction of ¹⁴N nuclei with local electric field gradients is characterized by a quadrupole coupling constant C_(Q) which can be as large as ˜1-3 MHz. In static powders or crystals, this leads to spectra with a width of several MHz which are difficult to excite uniformly and require broad probe and receiver bandwidths, thus limiting the sensitivity of the experiments. This problem also arises with other nuclei having a nuclear quadrupole moment Q as well as with paramagnetic samples where the spectra of the nuclei are broadened by hyperfine interactions with unpaired electrons.

In solid-state NMR, the first-order components of second-rank tensor interactions (e.g., dipolar couplings, anisotropic chemical shifts and quadrupole interactions) can be averaged out by magic angle spinning (MAS). Nevertheless, even with very fast spinning (ν_(rot)>50 kHz), ¹⁴N MAS NMR spectra are characterized by a large number of spinning sidebands [1], the envelope of which critically depends on several parameters [2].

In [3-5] application of trains of short pulses are disclosed (DANTE—Delay Alternating with Nutation for Tailored Excitation). In [5] DANTE sequences are used with MAS for selective inversion of a specific sideband family arising from one spin species (i.e. arising from the same sort of nuclei and having the same chemical shift) and selective excitation of a single spinning sideband.

It has been shown in recent years [6-7] that reliable ¹⁴N spectra can be obtained through indirect detection via a spy nucleus (typically ¹H or ¹³C) in the manner of heteronuclear single- and multiple-quantum correlation spectroscopy (HSQC and HMQC). So far, these methods have relied on the use of rectangular if pulses applied in the center of the nitrogen spectrum to excite heteronuclear multiple-quantum coherences comprising ¹⁴N single- or double-quantum (SQ or DQ) transitions and to reconvert these coherences back into observable single-quantum (SQ) coherences of the spy nuclei. The duration τ_(p) of the rectangular excitation and reconversion pulses applied to the ¹⁴N channel can be adjusted empirically, typically in the range 0.3 τ_(rot)<τ_(p)<0.6 τ_(rot). The efficiency of the coherence transfer process depends critically on the optimization of these pulses [2].

It is an object of the present invention to propose a method for performing magnetic resonance spectroscopy using MAS which enables uniform excitation of a great number of spinning sidebands and families of spinning sidebands with different chemical shifts that arise from large first-order quadrupole or hyperfine interactions.

It is a further object of the invention to improve signal intensity.

SUMMARY OF THE INVENTION

These objects are solved by a method according to the independent claim. According to the invention the broad-band excitation is carried out by applying a first train of rotor-synchronized rf-pulses (of rotor-synchronized DANTE sequence) with a carrier frequency to the nuclei of interest with a pulse duration 0.1 μs<τ_(p)<2 μs, the first train of rf-pulses comprising k·n pulses extending over k rotor periods τ_(rot) with n pulses per rotor period τ_(rot), where n is an integer n>1.

Excitation means the transfer from longitudinal to transverse magnetization of the spins of the nuclei of interest. The excitation of the transverse magnetization of the nuclei of interest is carried out while the sample is subjected to the static magnetic field.

The DANTE sequence used in the inventive method is rotor-synchronized, i.e., n equally spaced pulses are applied during each rotor period τ_(rot)=1/ν_(rot). A DANTE sequence in which n>1 pulses are applied during each rotor period τ_(rot) is called ‘overtone’ DANTE sequence. The use of an ‘overtone’ DANTE sequence leads to the suppression of spinning sidebands except those at ν₀±nν_(rot). The length τ_(train) of the ‘overtone’ DANTE sequence (pulse train) is shortened by a factor n compared to a ‘basic’ DANTE sequence (n=1). This reduces signal losses due to decay and thus enhances the signal intensity. The shorter the length τ_(train) of the pulse train the better the intensity of the signal. Thereby the inventive method allows one, e.g., to sample the indirect time domain t₁ of a 2D NMR measurement at dwell times equal to the rotor period/n instead of only the rotor period. Thereby significant gains in signal to noise can be achieved by collecting more points before the signal decays due to relaxation. In the indirect time domain t₁ the sidebands are folded in such a way to constructively add by synchronizing the dwell time of the indirect dimension with the rotor period divided by n.

The length τ_(train) of the pulse train determines the width 1/τ_(train) of the sidebands in the Fourier transform of said pulse train and thus the range of offsets of the spin species which can be excited by said pulse train. By using the inventive overtone DANTE sequence some of the spinning sidebands are suppressed and the spectral width can be increased thereby facilitating excitation in a broadband manner. In the inventive method the DANTE-sequence is preferably used for exciting multiple spin species that give rise to multiple families of sidebands. This can be achieved by using a pulse train of length τ_(train) that is shorter by a factor n compared to the length of a pulse train with n=1 which may be used for selective excitation of only one spin species, thereby broadening the sidebands of the rf-irradiation spectrum.

The inventive method results in an NMR-spectrum, in particular in a 1D or 2D spectrum. The nuclei of interest may comprise one or several species of the same sort of nuclei in different molecular environments, whereby different species of a nucleus differ in chemical shift, i.e. they are chemically inequivalent. Thus excitation of transverse magnetization of multiple species of one sort of nuclei and their corresponding spinning side band-families can be realized in a broadband manner, i.e. with a bandwidth larger than the radio-frequency intensity, in practice at least 10 kHz, preferably >100 kHz, normally <1 MHz. The bandwidth is most likely limited by the tuning of the probe.

The resonance signals arising from the afore described excitation can be detected with conventional NMR detection methods, thereby resulting in one or multidimensional NMR-spectra.

In a preferred variant of the inventive method the pulse duration τ_(p) is equal for all k·n pulses of the first train of pulses.

The inventive method is advantageous for examining samples containing nuclei showing broad spectra as stated in the description of the background of the invention. In preferred variant the nuclei of interest are nuclei with a nuclear quadrupolar moment with spin quantum number I=1, such as 14N or 2D.

Alternatively the nuclei of interest are quadrupolar nuclei with spin quantum number I=3/2 or 5/2 or 7/2.

The inventive method is also advantageous if the nuclei of interest have spin quantum number I=½, such as 13C or 15N, in particular comprised in paramagnetic samples, where the spectra of the nuclei of interest are broadened by hyperfine interactions with unpaired electrons.

It is advantageous that a reconversion of transverse magnetization into longitudinal magnetization is carried out by applying a second train of short rotor-synchronized rf-pulses, whereby the first train and the second train are separated by a variable evolution interval t₁. Reconversion means the transfer from transverse to longitudinal magnetization of the spins of the nuclei of interest and is carried out while the sample is subjected to said static magnetic field.

If the evolution interval is incremented it yields 2D spectra. If the evolution interval is not incremented 1D spectra of spy nuclei filtered through nuclei of interest can be achieved (e.g. 14N-filtered 1D spectra of S nuclei 1H or 13C), in case of a indirect excitation (see below).

In a preferred variant the first and the second train are equal with respect to the number n·k of pulses, the number k of rotor periods, the number n of pulses per rotor period and pulse duration τ_(p).

In a special variant of the inventive method the excitation of the nuclei of interest by the first train of short rotor-synchronized rf-pulses is carried out after: excitation of transverse magnetization from spy nuclei with spin quantum number S=½, in particular by using cross-polarization from protons 1H to the spy nuclei such as 13C, and an excitation interval τ_(exc), either without applying rf-irradiation, or with applying a multiple-pulse recoupling sequence to recouple the dipolar interactions between spy nuclei S and the nuclei of interest I, whereby the first train of short rotor-synchronized pulses is applied with a suitable carrier frequency immediately after the excitation interval τ_(exc). It is preferred to use 1H or 13C as spy nuclei. Typically, the number k of short pulses in k·τ_(rot) is chosen such that the length τ_(train) of the DANTE sequences are much longer than the rectangular excitation and reconversion pulses that were used hitherto in most indirect detection experiments. The recoupling allows the build-up of coherence of spin S in antiphase with respect to spin I. If no recoupling sequence is applied, the build-up of coherence of spin S in antiphase with respect to spin I can occur under the combined effects of scalar J-couplings and residual dipolar splittings, By applying the first train of short rotor-synchronized pulses heteronuclear multiple-quantum coherences comprising the nuclei of interest are excited (antiphase coherences are transferred into heteronuclear coherences).

It is preferred that following the second train of rotor-synchronized rf-pulses the reconversion of the magnetization of the nuclei of interest comprises a reconversion interval τ_(rec).

The evolution interval t₁ can be incremented, in particular in steps τ_(rot)/n, in the manner of heteronuclear single- or multiple-quantum two-dimensional correlation spectroscopy.

The evolution interval t₁ is preferably split into two equal intervals by a refocusing 180° rf-pulse applied to the S spins of the spy nuclei in order to refocus the frequency offset of the S spins of the spy nuclei with respect to the rf carrier frequency. The first and the second train are applied symmetrically with respect to the refocusing pulse, i.e., the time interval between end of first train and the center of the refocusing pulse is equal in duration to the time interval between the center of the refocusing pulse and beginning of the second train.

It is advantageous when the durations of the two halves of the split interval t₁ are incremented in steps of τ_(rot/)2n to achieve a greater bandwidth in the indirect dimension and reduce losses due to signal decay in the interval t₁.

Further advantages can be extracted from the description and the enclosed drawings. The features mentioned above and below can be used in accordance with the invention either individually or collectively in any combination. The embodiments mentioned are not to be understood as exhaustive enumeration but rather have exemplary character for the description of the invention.

The invention is shown in the drawing:

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1: shows excitation pulses for exciting transverse magnetization.

(a) a single rectangular pulse;

(b) a ‘basic’ DANTE scheme with k=8 (only 5 of which are shown) rotor-synchronized pulses;

(c)-(e) ‘overtone’ DANTE sequences with n=2 (c), 4 (d), and 8 (e) pulses per rotation period τ_(rot). The use of overtone DANTE sequences results in shortening of the train duration t_(train)=k·τ_(rot). 1/n.

FIG. 2: shows excitations profiles for direct excitation and observation of ¹⁴N magnetization in polycrystalline glycine spinning at ν_(rot)=62.5 kHz (rotation period τ_(rot)=16 μs), whereby:

(a) a single rectangular pulse of duration τ_(p)=3.5 μs and rf amplitude ω₁ (¹⁴N)/(2π)=ν₁(¹⁴N)=60 kHz (calibrated for NH₄Cl which has a very small quadrupolar coupling constant) was used for excitation. The envelope of the higher-order spinning sidebands is severely distorted;

(b) a ‘basic’ DANTE scheme with n=1 and k=13 rotor-synchronized pulses of τ_(p)=0.5 μs duration each in a total time 13τ_(rot)=208 μs was used for excitation;

(c)-(e) ‘overtone’ DANTE sequences with n=2 (c), 4 (d), and 8 (e) pulses per rotation period τ_(rot) are used for excitation. The use of overtone DANTE sequences results in the failure to excite sidebands that do not coincide with the Fourier components of the DANTE sequence at ν=ν_(rf)±kν_(rot) (as if the effective spinning frequency were multiplied by a factor k) while the amplitude of the even sidebands is boosted.

FIG. 3: shows schemes for the indirect detection of ¹⁴N nuclei I=1 via spy nuclei S=½ (here protons) by heteronuclear multiple-quantum correlation (HMQC) in solids spinning at the magic angle. In the interval τ_(exc)=pτ_(rot) (p is a positive integer), a recoupling sequence such as SR4² ₁ introduces a heteronuclear dipolar ¹H-¹⁴N coupling to allow for the creation of antiphase terms T^(S) _(1,m)T^(I) _(2,0) and T^(S) _(1,m)T^(I) _(1,0) with =±1. These can be transformed into heteronuclear coherences T^(S) _(1,m)T^(I) _(2,m′) and T^(S) _(1,m)T^(I) _(1m′) with m=±1 and m′=±1 or ±2 using one of the following three methods:

(a) A rectangular pulse with an rf amplitude on the order of ω₁(¹⁴N)/(2π)=60 kHz and a duration of 0.1 τ_(rot)<τ_(p)<0.6 τ_(rot), as in earlier work (here, τ_(p)=11 μs and τ_(rot)=16 μs).

(b) A ‘basic’ DANTE sequence (i.e., n=1 pulse per rotor period) with k short rotor-synchronized pulses with a typical duration τ_(p)=0.5 μs each and a typical rf amplitude ω₁(¹⁴N)/(2π)=60 kHz.

(c) ‘Overtone’ DANTE sequences with n pulses per rotation (shown as n=2) according to the invention.

FIG. 4: shows a cross-sections taken from 2D spectra of glycine, spinning at ν_(rot)=31.25 kHz in a static field of 18.8 T (800 MHz for protons).

(a) Conventional HMQC sequence using rectangular pulses with ω₁(¹⁴N)/(2π)=60 kHz and τ_(p)=18.3 μs.

(b)-(c) ‘Overtone’ DANTE HMQC sequence with n=2 and k=2, i.e., n·k=4 pulses of duration τ_(p)=1.5 μs each applied in 2τ_(rot)=64 μs.

(b) t₁ is sampled with increments Δt₁=τ_(rot) leading to a spectral width of ν_(rot), while

(c) t₁ is oversampled with increments Δt₁=½τ_(rot) and spectral width of 2ν_(rot). Oversampling the 2D spectrum (c) leads to a dramatic increase in signal-to-noise ratio.

FIG. 5: shows two-dimensional (2D) spectra of polycrystalline histidine spinning at ν_(rot)=62.5 kHz in a static field of 18.8 T (800 MHz for protons), showing correlations of single-quantum (SQ) ¹⁴N signals with those of neighboring protons.

(a) Conventional HMQC sequence of FIG. 3( a) using rectangular pulses with ω₁(¹⁴N)/(2π)=60 kHz and τ_(p)=11 μs.

(b) ‘Overtone’ DANTE HMQC sequence of FIG. 3( c) with n=2 and k=2, i.e., n·k=4 pulses of duration τ_(p)=1.1 μs each applied in 2τ_(rot)=32 μs.

FIG. 6: shows projections of the cross-peaks taken from the 2D HMQC spectra of FIG. 5 parallel to the ω₁ axis of the signals of nuclei N^(a), N^(b), and N^(c) in histidine.

(a) Conventional HMQC sequence of FIG. 3 a.

(b) ‘Basic’ DANTE sequence of FIG. 3 b with n=1 and k=8, i.e., n·k=8 pulses of τ_(p)=0.7 μs each in 8τ_(rot)=128 μs.

(c) ‘Overtone’ DANTE sequence of FIG. 3 c with n=2 and k=2, i.e., n·k=4 pulses of τ_(p)=1.1 μs each in 2τ_(rot)=32 μs.

DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 shows different possibilities for exciting a number of families of spinning sidebands that arise from large first-order quadrupole or hyperfine interactions. In the inventive method a conventional rectangular rf-pulse of duration τ_(p), which is known from the state of the art, is replaced with a DANTE sequence, i.e. with a train of k·n pulses within k rotor periods of n pulses per rotor period with pulse duration τ_(p). In the examples shown in FIG. 1 b-e each train comprises 8 rf-pulses (due to shortage of space only 5 of 8 rotor periods are shown in FIG. 1 b).

FIG. 1 b shows a ‘basic’ DANTE sequence with n=1 pulse per rotor period. It should be noted that the number of pulses of the train given in the example is only exemplary. In practice the number of pulses per train is chosen such that a desired flip angle of the spin of the nuclei of interest is achieved by irradiating the DANTE sequence.

Instead of k rotor periods with n=1 pulse per rotor period and pulse duration τ_(p), an ‘overtone’ DANTE sequence comprising k/n rotor periods with n pulses per rotor period and pulse duration τ_(p) can be applied (FIG. 1 c-e). The higher the number n of pulses per rotor period the shorter the train duration is (equal pulse durations and amplitudes assumed) for exciting the nuclei of interest with a given flip angle, thereby increasing the intensity of the signal.

The pulses within a sequence are equally spaced and rotor synchronized. The pulse duration τ_(p) may vary from pulse to pulse within a sequence. In most cases however the train comprises pulses of equal pulse length. The sequence is applied in order to excite transverse magnetization of the nuclei of interest. Other pulses that may be applied in order to produce other effects (e.g. inversion or refocusing) are not subjected to the restrictions mentioned in connection with the DANTE sequence.

By exciting transverse magnetization by using an inventive overtone DANTE sequence a great number of spinning sidebands families can be excited more uniformly while signal intensity is enhanced. The inventive method can be applied in one- and multi-dimensional NMR experiments.

FIG. 2 shows excitation profiles that can be achieved by direct excitation and detection of ¹⁴N using either a single rectangular pulse, a basic rotor-synchronized DANTE method with n=1, or ‘overtone’ DANTE sequences with n=2, 4, or 8 pulses per rotor period. The receiver bandwidth was set to 1 MHz and the pulse amplitude was calibrated to 60 kHz using ammonium chloride (NH₄Cl), which has a negligible quadrupole coupling. For the basic and overtone DANTE sequences, the number k of rotor periods and the pulse length τ_(p) were optimized empirically to achieve the largest transverse magnetization. With n=1, the radio-frequency irradiation sidebands of the DANTE sequence coincide with the spinning sidebands, provided the carrier frequency coincides with one of the spinning sidebands. With n=2, the radio-frequency irradiation sidebands of the DANTE sequence coincide with even spinning sidebands, provided the carrier frequency coincides with one of the spinning sidebands. With n=4, the radio-frequency irradiation sidebands of the DANTE sequence coincide with every fourth spinning sideband, provided the carrier frequency coincides with one of the spinning sidebands, etc.

FIG. 3 shows schemes for the indirect detection of ¹⁴N. The indirect detection of ¹⁴N exploits the transfer of coherence between single- or double-quantum (SQ or DQ) coherences of nitrogen-14 and SQ coherences of suitable spy nuclei with spin S=½ such as ¹H or ¹³C, as described in detail elsewhere [2, 6-12]. k is known that the transfer of coherence can be achieved via residual dipolar splitting (RDS) [2,6], via scalar couplings [7,8] or via heteronuclear dipolar interactions, provided these are ‘recoupled’ by suitable pulse sequences as described in [10,11].

At the end of the excitation interval τ_(exc) (see FIG. 3), these interactions lead to a state that can be described by spin tensor product operators T^(S) _(1,m)T^(I) _(2,0) and T^(S) _(1,m)T^(I) _(1,0), with m±1. At this point, the coherence order for spin I (i.e., ¹⁴N) is still p_(I)=0, whereas for spin S (i.e., ¹H or ¹³C) one has coherence orders p_(S)±1. In the ¹⁴N NMR experiments described by Cavadini et al. [2], SQ or DQ coherences of the ¹⁴N spin I of order p_(I)±1 or p_(I)±2 are created by applying an rf pulse within about 10 kHz of the centre of the quadrupolar doublet of the nitrogen spectrum. These coherences are allowed to evolve freely during the evolution time at the end of which they are symmetrically reconverted back into observable SQ coherences T^(S) _(1,m) of the spy nucleus. The optimum duration τ_(p) of the excitation and reconversion ¹⁴N pulses depends on the spinning frequency and on the quadrupole coupling constant C_(Q), and must be optimized experimentally. For a sample of L-alanine (C_(Q)=1.13 MHz) spinning at τ_(rot)=30 kHz using an rf amplitude ν₁(¹⁴N)=57 kHz, the optimum [2] is τ_(p)˜11 μs (τ_(p)/τ_(rot)˜⅓) for ¹⁴N SQ (p_(I)=±1) and τ_(p)˜22 μs (τ_(p)˜τ_(rot)˜⅔) for ¹⁴N DQ (p_(I)=±2), suggesting a compromise τ_(p)˜16 μs˜0.5τ_(rot) (τ_(p)/τ_(rot)˜½). The global excitation-reconversion efficiency was about 16% and 13% for SQ and DQ coherences, respectively.

In the inventive method the rectangular nitrogen-14 pulses of duration τ_(p) are replaced with DANTE sequences, i.e., k rotor periods with n pulses per rotor period. In the example shown in FIG. 3 (indirect detection of ¹⁴N via protons) the number of rotor periods is 2<k and the pulse durations are τ_(p)˜0.7 μs or shorter. In analogy to a rectangular ¹⁴N pulse, the first DANTE sequence induces heteronuclear MQ coherences involving ¹⁴N SQ and DQ coherences. After the t₁ evolution interval, the second DANTE sequence allows one to reconvert these heteronuclear coherences back into the states T^(S) _(1,m)T^(I) _(2,0) and T^(S) _(1,m)T^(I) _(1,0). The excitation and reconversion DANTE sequences preferably have the same numbers n, k and duration τ_(p). Nevertheless the inventive method can be carried out according to the scheme of FIG. 3 with the excitation DANTE sequence having numbers n, k and duration τ_(p) different than the reconversion DANTE sequence. The reconversion DANTE sequence can also be replaced by a rectangular pulse.

The phase cycles described by Cavadini et al. [2] allow one to select the desired coherence pathways, i.e., to select ¹⁴N SQ or DQ coherences. In this work only results from the SQ pathway are presented. Yet, the invention can be also used for DQ. The efficiency of the scheme has been optimized by varying both the number k of rotor periods for each DANTE sequence and the duration τ_(p) of the individual pulses. Experiments on polycrystalline samples of Glycine and Histidine spinning at ν_(rot)=62.5 kHz and ν_(rot)=31,25 kHz (τ_(rot)=16 μs, τ_(rot)=32 μs) are carried out, in a static magnetic field B₀=18.9 T corresponding to a proton Larmor frequency of 800 MHz.

The present invention shows that the conventional rectangular excitation and reconversion pulses (FIG. 3 a) at the beginning and end of the evolution time t₁ can be replaced by rotor-synchronized DANTE sequences. Typically, with n=1 pulse per rotor period, one may use k=12 short pulses in 12τ_(rot), so that the DANTE sequences are much longer than the rectangular excitation and reconversion pulses that were used hitherto in most indirect detection experiments. To limit signal decay due to dipolar interactions, DANTE experiments are therefore best carried out at spinning frequencies higher that 30 kHz.

Comparing direct excitation with a single rectangular pulse or with DANTE sequences (FIG. 2 a and FIG. 2 b) it can be seen that the latter scheme allows one to achieve a much more uniform excitation of many spinning sidebands. ‘Overtone’ DANTE sequences with n=2, 4 and 8 pulses per rotor period (FIG. 2 c-e) lead to spectra where, in addition to the centerband that coincides with the carrier frequency ν_(rf), only spinning sidebands spaced at ν_(rf)±nν_(rot) (where n=2, 4 and 8) appear. It should be noted that the number of pulses per rotation period is not limited to n=2, 4 and 8. Note that ‘overtone’ DANTE sequences produce sideband patterns (FIG. 2 c-e) that are similar to what would be expected if the spinning frequency could be boosted to nν_(rot). In the indirect t₁ dimension (FIG. 3 c), this allows one to oversample by using small increments Δt₁=τ_(rot)/n. This leads to an n-fold increase of the spectral width in the ω₁ domain, and provides a boost in signal-to-noise ratio by acquiring more points before the signal decays, and by spreading the noise across a larger spectrum. This is shown in FIG. 4 where in the ω₁ dimension the spectrum of glycine, spinning at 31.250 kHz, is acquired with the normal HMQC sequence (FIG. 4 a) the ‘overtone’ DANTE (n=2) with normal sampling (FIG. 4 b) and with oversampling (FIG. 4 c).

Most solid-state NMR spectrometers are not designed to deliver sub-microsecond pulses. In practice, the rising and falling edges of the pulse shapes will be distorted, inter alea because of the high quality Q factors of the probes. Fortunately, it turns out that DANTE sequences are quite forgiving.

The DANTE sequences, in particular overtone DANTE sequences with n>1 which have a short duration τ_(train),=kτ_(rot) are relatively broadband and can excite several families of sidebands that have one sideband near the carrier frequency, since the widths of the sidebands in the radio-frequency spectrum are proportional to 1/τ_(train). The spectra in FIGS. 5 and 6 indicate that a single DANTE sequence can excite several isotropic shifts spanning at least 10 kHz if the rf amplitude is 60 kHz. The shifts in the N14 dimension are small, and they all fall within the width of a single sideband of the radio-frequency irradiation of the DANTE sequence.

The DANTE approach described above was combined with indirect (proton) detection of ¹⁴N SQ by HMQC. Using a basic rotor-synchronized DANTE scheme (n=1 pulse per rotor period, k=13 rotor periods), the spectra of FIG. 6 show that the gain in the excitation efficiency is sufficient to compensate for the dramatic T₂′ losses during k=13 rotor periods. It is of advantage to spin the sample at high spinning speeds to reduce the losses in the interval kτ_(rot). For glycine, which has a small quadrupole interaction C_(Q)=1.18 MHz, the efficiency of the basic DANTE sequence is comparable to an HMQC sequence with rectangular pulses. For the aromatic nitrogen nuclei in histidine, which have larger quadrupolar coupling constants (C_(Q)˜1-3 MHz), one notices a significant improvement with DANTE (FIG. 5). All three nitrogen sites in histidine N^(a) (=NH₃₊), N^(b)(=acidic aromatic NH), and N^(c) (=basic aromatic N) could be excited and resolved in the indirect dimension, while in the conventional HMQC spectrum only the N^(a) resonance, which has the smallest quadrupole interaction, could be excited. The improvement of the excitation is illustrated in FIG. 6 by comparing cross-sections through the 2D spectra of FIG. 5. Note the dramatic improvement for the aromatic N^(b)H and N^(c) sites, which have much larger quadrupolar coupling constants than N^(a)H₃. The best excitation is obtained by using an ‘overtone’ DANTE sequence with n=2 pulses per rotor period and k=2 rotor periods, each of duration τ_(p)=1.1 μs, both for excitation and reconversion.

Although the before described examples concern 14N the same principle can be applied to a large number of other nuclei, e.g., with spin quantum number I=1, such as 14N or 2D, with spin quantum number I=3/2 or 5/2 or 7/2 or with spin quantum number I=½, such as 13C or 15N, in particular comprised in paramagnetic samples, where the spectra of the nuclei of interest are broadened by hyperfine interactions with unpaired electrons.

It has been shown that a train of short rotor-synchronized pulses in the manner of Delays Alternating with Nutations for Tailored Excitation (DANTE) applied to nuclei of interest in samples spinning at the magic angle at high frequencies (e.g., ν_(rot)=62.5 kHz so that τ_(rot)=16 μs) allows one to achieve uniform excitation of a great number of spinning sidebands that arise e.g. from large first-order quadrupole interactions, as occur for aromatic nitrogen-14 nuclei in histidine. With routine rf amplitudes ω₁(¹⁴N)/(2π)=60 kHz and very short pulses of a typical duration 0.5<τ_(p)<2 μs, efficient excitation can be achieved with k=13 rotor-synchronized pulses in 13 τ_(rot)=208 μs. Alternatively, with ‘overtone’ DANTE sequences using n=2, 4, or 8 pulses per rotor period one can also achieve more efficient broadband excitation in fewer rotor periods, typically 2-4 τ_(rot). These principles can be combined with the indirect detection of ¹⁴N nuclei with I=1 via spy nuclei with S=½ such as 1H or ¹³C in the manner of heteronuclear multiple-quantum correlation spectroscopy (HMQC).

There is a considerable advantage in replacing rectangular excitation pulses by rotor-synchronized DANTE sequences. This can be beneficial both for direct excitation of ¹⁴N spectra and for indirect detection via spy nuclei such as ¹H or ¹³C. To limit signal decay, DANTE experiments are best carried out at very high spinning frequencies.

The basic and overtone DANTE schemes presented here may be more broadly applicable to many spinning samples where the breadth of the spectrum is many times larger than both the MAS frequency and the available RE field strength. For half-integer quadrupolar nuclei this may significantly improve the excitation and detection of the satellite transitions. These methods may even be useful for spin ½ nuclei in situations of MAS with spinning frequencies below 30 kHz and RF field strengths below 10 kHz. This may be especially relevant for the case of unpaired electrons in paramagnetic systems undergoing MAS as found in some dynamic nuclear polarization (DNP) experiments. Rotor-synchronized microwave pulses may be useful to manipulate the electron spins for DNP.

REFERENCES

-   [1] T. Giavani, H. Bildsoe, J. Skibsted, H. J. Jakobsen, J. Phys.     Chem. B 106 (2002) 3026. -   [2] S. Cavadini, S. Antonijevic, A. Lupulescu, G. Bodenhausen,     ChemPhysChem 8 (2007) 1363. -   [3] G. Bodenhausen, R. Freeman, G. A. Morris, J Magn. Reson.     23 (1976) 171. -   [4] G. A. Morris, R. Freeman, J Magn. Reson. 29 (1978) 433. -   [5] P. Caravatti, G. Bodenhausen, R. R. Ernst, J Magn. Reson.     55 (1983) 88. -   [6] S. Cavadini, A. Lupulescu, S. Antonijevic, G. Bodenhausen, J.     Am. Chem. Soc. 128 (2006) 7706. -   [7] Z. Gan, J. Am. Chem. Soc. 128 (2006) 6040. -   [8] S. Cavadini, S. Antonijevic, A. Lupulescu, G. Bodenhausen, J.     Magn. Reson. 182 (2006) 168. -   [9] S. Cavadini, Prog. Nucl. Magn. Reson. Spectrosc. 56 (2010) 46. -   [10] Z. Gan, J. P. Amoureux, J. Trebosc, Chem. Phys. Lett.     435 (2007) 163. -   [11] S. Cavadini, A. Abraham, G. Bodenhausen, Chem. Phys. Lett.     445 (2007) 1. -   [12] S. Cavadini, V. Vitzthum, S. Ulzega, A. Abraham, G.     Bodenhausen, J. Magn. Reson. 1 (2010) 57. 

1. A method for performing magnetic resonance spectroscopy on a solid sample containing nuclei of interest having spin quantum number I, the method comprising the steps of: a) subjecting the sample to a static magnetic field; b) spinning the sample at a magic angle; and c) exciting, in a broad-band manner, a transverse magnetization of the nuclei of interest by applying a first train of rotor-synchronized rf-pulses, having a carrier frequency, to the nuclei of interest with a pulse duration 0.1 μs<τ_(p)<2 μs, the first train of rf-pulses comprising k·n pulses extending over k rotor periods τ_(rot) with n pulses per rotor period τ_(rot), wherein n is an integer n>1.
 2. The method of claim 1, wherein the pulse duration τ_(p) is equal for all k·n pulses of the first train of pulses.
 3. The method of claim 1, wherein the nuclei of interest are nuclei with a nuclear quadrupolar moment having spin quantum number I=1, 14N nuclei or 2D nuclei.
 4. The method of claim 1, wherein the nuclei of interest are quadrupolar nuclei having spin quantum number I=3/2, 5/2 or 7/2.
 5. The method of claim 1, wherein the nuclei of interest have spin quantum number I=½, are 13C or are 15N.
 6. The method of claim 5, wherein the nuclei of interest are comprised in paramagnetic samples, spectra of the nuclei of interest thereby being broadened by hyperfine interactions with unpaired electrons.
 7. The method of claim 1, wherein a reconversion of transverse magnetization into longitudinal magnetization is carried out by applying a second train of short rotor-synchronized rf-pulses, the first train and the second train being separated by a variable evolution interval t₁.
 8. The method of claim 7, wherein the first and the second train are equal with respect to a number n·k of pulses, a number k of rotor periods, a number n of pulses per rotor period and the pulse duration τ_(p).
 9. The method of claim 1, wherein excitation of the nuclei of interest by the first train of short rotor-synchronized rf-pulses is carried out subsequent to the following steps: a1) exciting transverse magnetization of spy nuclei with spin quantum number S=½; and b1) waiting an excitation interval τ_(exc), either without applying rf-irradiation or with applying a multiple-pulse recoupling sequence to recouple dipolar interactions between the spy nuclei S and the nuclei of interest I, wherein the first train of short rotor-synchronized pulses is applied with a suitable carrier frequency immediately after the excitation interval τ_(exc),
 10. The method of claim 9, wherein step a1) comprises cross-polarization from protons to the spy nuclei.
 11. The method of claim 7, wherein excitation of the nuclei of interest by the first train of short rotor-synchronized rf-pulses is carried out subsequent to the following steps: a1) exciting transverse magnetization of spy nuclei with spin quantum number S=½; and b1) waiting an excitation interval τ_(exc), either without applying rf-irradiation or with applying a multiple-pulse recoupling sequence to recouple dipolar interactions between the spy nuclei S and the nuclei of interest I, wherein the first train of short rotor-synchronized pulses is applied with a suitable carrier frequency immediately after the excitation interval τ_(exc),
 12. The method of claim 11, wherein, after the second train of rotor-synchronized rf-pulses, reconversion of magnetization of the nuclei of interest I to transverse magnetization of spy nuclei S is achieved during a reconversion interval τ_(rec).
 13. The method of claim 7, wherein the evolution interval t₁ is incremented in a manner of heteronuclear single- or multiple-quantum two-dimensional correlation spectroscopy.
 14. The method of claim 11, wherein the evolution interval t₁ is split into two equal intervals by a refocusing 180° pulse applied to S spins of the spy nuclei in order to refocus a frequency offset of the S spins of the spy nuclei with respect to the rf carrier frequency.
 15. The method of claim 14, wherein durations of two halves of a split interval t₁ are incremented in steps of τ_(rot/)2n to achieve a greater bandwidth in an indirect dimension and to reduce losses due to signal decay in the interval t₁. 